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UNIT 3 | ELECTROMAGNETIC THEORY

3.1 Static Magnetic Field

Welcome to Unit 3 of our CE402 Electrical Engineering series, where we embark on a thrilling journey into the world of the Static Magnetic Field. This unit is designed to provide you with a comprehensive understanding of fundamental concepts that shape magnetic phenomena.

3.0 Introduction to Static Magnetic Field:
Join us as we lay the groundwork for understanding the Static Magnetic Field, exploring its significance in the realm of electrical engineering.

3.1 Static Magnetic Field:
Delve into the intricacies of the Static Magnetic Field, unraveling the relationships between magnetic flux, flux density, and magnetic field intensity. Explore the concept of current densities and the role of individual current elements.

3.2 Biot-Savart Law:
Uncover the secrets of the Biot-Savart Law, a key principle in calculating magnetic fields generated by current-carrying conductors.

3.3 Magnetic Field Intensity:
Understand the magnetic field intensity resulting from straight current-carrying filaments, both infinite and finite in length.

3.4 Ampere’s Circuital Law:
Explore Ampere’s Circuital Law, a fundamental tool in understanding the magnetic field around electric currents.

3.5 Application of Ampere’s Circuital Law:
Witness the application of Ampere’s Circuital Law in various electrical engineering contexts. Explore how this fundamental law is used to analyze and predict magnetic fields around different current configurations.

3.6 Ampere’s Circuital Law in Point Form: Maxwell’s Equation:
Unravel the elegance of Ampere’s Circuital Law expressed in point form, a key component of Maxwell’s Equations. Understand the theoretical underpinnings and implications of this formulation in the broader electromagnetic theory.

3.7 Stoke’s Law & Curl:
Dive into Stoke’s Law and the concept of Curl, gaining insights into the physical interpretation of this mathematical operator in the context of magnetic fields.

3.8 Curl and Physical Interpretation:
Explore the concept of curl, a mathematical operator that describes the rotation and circulation of a vector field. Gain insights into the physical interpretation of curl, unraveling its significance in understanding the behavior of magnetic fields.

3.9 Problems based on Ampere’s Circuital Law:
Challenge your problem-solving skills with scenarios involving Ampere’s Circuital Law. Tackle problems that require a deep understanding of magnetic fields and their complexities.

3.10 Problems Based on Curl:
Engage in problem-solving exercises centered around the concept of curl. Strengthen your analytical skills by addressing challenges related to the rotation and circulation of vector fields in magnetic scenarios.

3.11 Magnetic Force:
Investigate magnetic forces and discover the fascinating interactions between long and parallel current-carrying conductors.

3.12 Force between Two long and parallel current-carrying conductors:
Delve into the forces at play between long, parallel current-carrying conductors. Understand the nuances of these interactions, a fundamental aspect of understanding magnetic fields in real-world applications.

3.13 Flux Linkages:
Uncover the concept of flux linkages and their role in magnetic circuits. Explore how magnetic fields induce voltages in coils and understand the practical implications of this phenomenon.

3.14 Four Maxwell’s Equations:
Explore the elegance of Maxwell’s Equations, the cornerstone of electromagnetic theory that unifies electric and magnetic phenomena.

3.15 Torque on a current carrying loop: Magnetic Moment:
Explore the torque experienced by a current-carrying loop in a magnetic field, leading to the concept of magnetic moment. Gain insights into how these phenomena contribute to the behavior of magnetic systems.

3.16 Lorentz Force:
Dive into the Lorentz Force, a fundamental force experienced by charged particles in magnetic fields. Understand its role in various electrical engineering applications and explore the mathematical expressions that govern this force.

3.17 Magnetic Boundary Conditions:
Navigate through the challenges posed by magnetic boundary conditions, understanding how magnetic fields behave in different scenarios.

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